Post on 03-Oct-2020
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The uremic toxin indoxyl sulfate interferes with iron
metabolism by regulating hepcidin in chronic kidney disease
Hirofumi Hamano1,2*, Yasumasa Ikeda1*, Hiroaki Watanabe3*, Yuya Horinouchi1, Yuki
Izawa-Ishizawa1, Masaki Imanishi2, Yoshito Zamami2,3, Kenshi Takechi4, Licht
Miyamoto5, Keisuke Ishizawa2,3, Koichiro Tsuchiya5, Toshiaki Tamaki1
1Department of Pharmacology, Institute of Biomedical Sciences, Tokushima University
Graduate School, Tokushima, Japan
2Department of Pharmacy, Tokushima University Hospital, Tokushima, Japan
3Department of Clinical Pharmacy, Institute of Biomedical Sciences, Tokushima
University Graduate School, Tokushima, Japan
4Clinical Trial Center for Developmental Therapeutics, Tokushima University Hospital
5Department of Medical Pharmacology, Institute of Biomedical Sciences, Tokushima
University Graduate School, Tokushima, Japan
*These authors contributed equally to this work.
Corresponding author: Yasumasa Ikeda, MD, PhD
Department of Pharmacology, Institute of Biomedical Sciences,
Tokushima University Graduate School,
3-18-15 Kuramoto-cho, Tokushima, 770-8503, Japan
E-mail: yasuike@tokushima-u.ac.jp
Tel: +81-88-633-7061, Fax: +81-88-633-7062
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Abstract
Background: Hepcidin secreted by hepatocytes is a key regulator of iron metabolism
throughout the body. Hepcidin concentrations are increased in chronic kidney disease
(CKD), contributing to abnormalities in iron metabolism. Levels of indoxyl sulfate (IS),
a uremic toxin, are also elevated in CKD. However, the effect of IS accumulation on
iron metabolism remains unclear.
Methods: We used HepG2 cells to determine the mechanism by which IS regulates
hepcidin concentrations. We also used a mouse model of adenine-induced CKD. The
CKD mice were divided into two groups: one was treated using AST-120 and the other
received no treatment. We examined control mice, CKD mice, CKD mice treated using
AST-120, and mice treated with IS via drinking water.
Results: In the in vitro experiments using HepG2 cells, IS increased hepcidin
expression in a dose-dependent manner. Silencing of the aryl hydrocarbon receptor
(AhR) inhibited IS-induced hepcidin expression. Furthermore, IS induced oxidative
stress, and antioxidant drugs diminished IS-induced hepcidin expression.
Adenine-induced CKD mice demonstrated an increase in hepcidin concentrations; this
increase was reduced by AST-120, an oral adsorbent of the uremic toxin. CKD mice
showed renal anemia, decreased plasma iron concentration, increased plasma ferritin,
and increased iron content in the spleen. Ferroportin was decreased in the duodenum
and increased in the spleen. These changes were ameliorated by AST-120 treatment.
Mice treated by direct IS administration showed hepatic hepcidin upregulation.
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Conclusion: IS affects iron metabolism in CKD by participating in hepcidin regulation
via pathways that depend on AhR and oxidative stress.
Keywords: Indoxyl sulfate, hepcidin, iron, CKD, anemia
Running Head
Effect of indoxyl sulfate on hepcidin regulation
Short summary
In contrast with absolute iron deficiency, functional iron deficiency is common, and it
causes renal anemia in chronic kidney disease. In the present study, we found that
indoxyl sulfate (IS)—a uremic toxin—contributes to renal anemia by regulating
hepcidin concentrations and thus impairing iron absorption and causing ectopic iron
accumulation. This study presents the first findings regarding the effect of IS on
hepcidin concentrations and thus on whole-body iron metabolism in CKD.
Introduction
As the incidence of chronic kidney disease (CKD) has increased worldwide,
morbidity and mortality in the general population have worsened [1, 2]. Patients with
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CKD often have renal anemia, and they are generally treated using both iron
supplementation and an erythropoiesis-stimulating agent (ESA). However, in
individuals with CKD, iron treatment may lead to over supplementation due to
functional iron deficiency.
Hepcidin is a secreted protein mainly derived from the liver that plays a crucial
role in the regulation of iron metabolism [3]. Specifically, hepcidin regulates iron
efflux from intracellular iron by inducing the internalization and degradation of
ferroportin (FPN), a cellular iron exporter [4]. Hepcidin levels are increased in patients
with CKD [5], as well as in experimental animal models of CKD [6, 7]. Increased
hepcidin levels in patients with CKD may impair the proper use of stored iron and lead
to FPN degradation, thereby contributing to functional iron deficiency and
dysregulation of iron metabolism.
Indoxyl sulfate (IS) is a protein-bound uremic toxin and a metabolite of indole, a
tryptophan metabolite that is synthesized by intestinal bacteria. In healthy subjects, IS
is excreted in the urine via the renal proximal tubule; however, patients with impaired
renal function show reduced excretion of IS, and it accumulates in their blood [8]. The
accumulation of IS further predicts renal dysfunction in CKD [9], and high serum IS
levels are associated with cardiovascular diseases and mortality in CKD patients [10].
IS also induces reactive oxygen species (ROS) as well as inflammation, and exerts
adverse effects on various organs [11]. AST-120, a sorbent of uremic toxin, has been
shown to ameliorate CKD-related complications [12-19].
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Regarding renal anemia in CKD, IS accumulation inhibits the hypoxia-inducible
factor and thus reduces EPO production [20]. Furthermore, IS removal improves the
effect of ESA on anemia in late-stage CKD patients [21], indicating that IS mediates
renal anemia via EPO regulation. However, it is not completely clear how IS
accumulation impacts iron metabolism in CKD.
In the present study, we evaluated the effect of IS on iron metabolism, and found
that IS augments hepatic hepcidin production, and in a mouse model of
adenine-induced CKD, mice with a high IS concentration showed increased hepatic
and plasma hepcidin levels, decreased ferroportin expression in the duodenum, and
increased iron content in the spleen. These changes were ameliorated by AST-120
treatment. Our findings suggest that IS accumulation leads to increases in hepcidin,
which in turn dysregulates iron metabolism in CKD.
Materials and Methods
Chemicals and reagents
Indoxyl sulfate potassium salt, adenine sulfate, and AST-120 (Kremezin™)
were purchased from Sigma-Aldrich (St. Louis, MO, USA), Wako Pure Chemical
Industries, Ltd. (Osaka, Japan), and Kureha Corporation (Tokyo, Japan), respectively.
N-acetyl cysteine (NAC), an antioxidant drug, and CH-223191, an inhibitor of AhR,
were obtained from Sigma-Aldrich. The following commercially available antibodies
were used for this study: anti-NRAMP2 (DMT1) antibody, anti-ferritin heavy chain
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(FTH), anti-ferritin light chain (FTL), and anti-AhR antibody (Santa Cruz
Biotechnology, Santa Cruz, CA, USA); anti-transferrin receptor 1 (TfR1) antibody
(Zymed Technologies; Carlsbad, CA, USA); anti-FPN antibody (Alpha Diagnostics;
San Antonio, TX, USA); anti-α-tubulin (San Diego, CA, USA), which was used as a
protein loading control; and anti-Histone H3 antibody (Abcam, Cambridge, UK),
which was used as a loading control in the case of nuclear proteins.
Experimental animals and treatment
All experimental procedures involving animals were performed in
accordance with the guidelines of the Animal Research Committee of Tokushima
University Graduate School (Permit Number: 13095). Eight-week-old male C57BL6/J
mice were purchased from Nippon CLEA (Tokyo, Japan). The mice were maintained
under conventional conditions, with a regular 12-hour light/dark cycle and free access
to food (Type NMF; Oriental Yeast, Tokyo, Japan) and water during the study. Dietary
adenine administration has been used to induce CKD in rodents [22]. [Animal
experiment 1]: We used a new protocol involving intraperitoneal adenine
administration, as previously described [23]; however, we modified the protocol of the
previous study in that we administered 100 mg/kg of adenine three times per week for
four weeks. One week after the start of adenine administration, serum creatinine was
elevated by approximately twofold (vehicle vs. adenine: 0.50 ± 0.07 mg/dL vs. 0.87 ±
0.15 mg/dL; p < 0.01); the mice that were receiving adenine were then divided into two
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groups and treated for three more weeks; specifically, a “normal diet” group and an
“AST-120” group, in which the normal diet was supplemented with 5% AST-120,
were established [13, 19]. A control group received a normal diet, as well as
intraperitoneal vehicle administration. [Animal experiment 2]: To test the direct IS
effect on hepcidin, 0.1% IS (200 mg (800 µmol)/kg/day) was administered to the mice
in their drinking water for two weeks as previously described [19]. The mice were
euthanized by intraperitoneal over-dose injection of pentobarbital, their blood was
collected, and their tissue was removed and stored at -80°C until use.
Hematological analysis
Whole blood cell counts were performed by Shikoku Chuken Co. Ltd.
(Kagawa, Japan), and serum creatinine levels were determined using an alkaline picrate
based assay (LabAssay Creatinine Kit, Wako Pure Chemical Industries Ltd., Osaka,
Japan).
Measurement of plasma iron levels, plasma ferritin levels, and tissue iron
concentration
Plasma iron levels and tissue iron concentrations were measured using an
iron assay kit according to the manufacturer’s instructions (Metallo Assay;
Metallogenics Co. Ltd.; Chiba, Japan), as previously described [24-26]. Plasma ferritin
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levels were determined by a Mouse Ferritin ELISA Kit (Immunology Consultants
Laboratory, Newberg, OR) according to the manufacturer’s instructions.
Cell culture
HepG2, a human hepatoma cell line, was purchased from the Japanese
Collection of Research Bioresources (Osaka, Japan). The methods of cell culture have
been previously described [26]. In some experiments, the cells were pre-treated for one
hour with either 100 µM tempol (ROS scavenger), 10 µM BAY11-7082 (NF-κB
inhibitor), 100 µM NAC (antioxidant drug), or 10 µM CH-223191 (AhR inhibitor)
before stimulation with IS. In other experiments, HepG2 cells were cultured in bovine
serum albumin (BSA) (40g/L) containing DMEM [11]. BSA was purchased from
Wako Pure Chemical Industries, Ltd., and the concentration of endotoxin in BSA
solution was 0.03 ng/mL as detected using a Limulus Amebocyte Lysate assay
(Pierce™ LAL Chromogenic Endotoxin Quantitation Kit, Thermo Fisher Scientific Inc.
Waltham, MA, USA).
RNA extraction and evaluation of mRNA expression levels
The RNA extraction, cDNA synthesis, and quantitative RT-PCR methods
have been described previously [25]. The primer sets used were as follows: 5′
-ATGTCGCCTCCAGATACCAC-3′ and 5′-CCTCTCCCGTGTACAGCTTC-3′
for mouse erythropoietin (EPO), 5′-CTGCCTGTCTCCTGCTTCTC-3′ and 5′-
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AGATGCAGATGGGGAAGTTG-3 ′ for mouse hepcidin-1, 5 ′
-CTCCGAACAATCACTGCTGA-3′ and 5′-CCTCCCCTGTGTSCSGCTTC-3′
for human hepcidin, 5 ′ -CTGCCTTTCCCACAAGATGT-3 ′ and 5 ′
-CAGTTATCCTGGCCTCCGTTT-3 ′ for human AhR, and 5 ′
-GCTCCAAGCAGATGCAGCA-3′ and 5′ -CCGGATGTGAGGCAGCAG-3′
for 36B4 as an internal control. The expression levels of all target genes were
normalized using 36B4, and the values were compared to the control group in terms of
relative fold changes.
Protein extraction and western blot analysis
Protein preparation was done and western blotting was performed as
previously described [25]. Densitometry of the visualized bands was quantified using
Image J 1.38x software. Protein staining by Ponceau S solution was used as a protein
loading control in the duodenum.
Measurement of intracellular reactive oxidative species levels
Intracellular ROS were detected using dichlorofluorescin diacetate
(DCFH-DA; Sigma-Aldrich). HepG2 cells were stimulated, for various time periods,
using 250 µM IS; then, they were incubated with 10 µM DCFH-DA at 37°C for 30
minutes. After washing, ROS production was quantified at 488 and 532 nm using a
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microplate reader (FilterMax F3 Multi-Mode Microplate Reader; Molecular Devices
LLC, Sunnyvale, CA, USA).
Small interfering RNA experiments
Small interfering RNA (siRNA) targeting human AhR and a non-targeting
siRNA control sequence were commercially obtained from Sigma Aldrich (Mission
siRNA; Tokyo, Japan). Transfection was performed as previously described [26].
Briefly, subconfluent HepG2 cells were transfected for 24 hours with 25 nM siRNA
using the RNAiMAX® reagent and OPTI-MEM® (Life Technologies, Inc.). In all
experiments, transfected HepG2 cells were used 48 hours after transfection.
Measurement of IS and hepcidin concentrations in plasma and cell culture medium
IS levels in mouse plasma were measured using high performance liquid
chromatography. The concentrations of human and mouse hepcidin-25 were
quantitatively analyzed as previously described [27]. In brief, surface-enhanced laser
desorption ionization time of flight mass spectrometry (SELDI-TOF MS) was used to
analyze hepcidin-25. The molecular sizes of peptides at 2789 m/z matched with the
reported sizes of hepcidin-25, and the serum peptide at 2789 m/z was identified as
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hepcidin-25 by collision-induced dissociation tandem MS. The assays were performed
by Medical Care Proteomics Biotechnology Co. Ltd. (Kanazawa, Japan).
Evaluation of iron-regulatory protein iron-responsive element binding activity
The interaction between iron-regulatory protein (IRP) and iron-responsive
element (IRE) was evaluated using an EMSA kit (LightShift Chemiluminescent RNA
EMSA Kit; Thermo Fisher Scientific Inc., Rockford, IL, USA) as previously reported
[24]. Semi-quantification for IRP-IRE binding activity was performed using ImageJ
1.38X software.
Statistical analysis
Data are presented as means ± standard deviation (SD). An unpaired, 2-tailed,
Student’s t-test was used for comparisons between the two groups. For comparisons
between more than two groups, the statistical significance of each difference was
evaluated using a post-hoc test (either Dunnett’s method or Tukey-Kramer’s method).
P-values < 0.05 indicated statistical significance.
Results
Effect of IS on hepcidin expression in liver and cultured hepatic cell line
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IS stimulated hepcidin mRNA expression in a dose-dependent manner in
HepG2 cells (Figure 1A). Similarly, hepcidin secreted from HepG2 cells was increased
by IS stimulation (Figure 1B). AhR is a receptor for IS, and activated AhR is
translocated from the cytosol to the nucleus, where it promotes the transcription of
target genes [28]. Indeed, IS stimulation promoted nuclear translocation of AhR in
HepG2 cells at 30 minutes or later in the present study (Figure 1C). Therefore, we used
RNA interference to check whether AhR is involved in IS-induced hepcidin
upregulation and observed that the siRNA reduced AhR mRNA levels to 27.0 ± 3.0%
of the control (p < 0.01) and reduced AhR protein levels to 38.9 ± 16.7% of the control
(p < 0.01). Silencing of AhR diminished IS-induced hepcidin expression (Figure 1D).
Similarly, pharmacological AhR inhibition using CH-223191 suppressed IS-induced
hepcidin expression (Figure 1E). These findings suggest that IS increases hepcidin
expression via an AhR-mediated pathway.
Influence of albumin on IS-induced hepcidin expression
Uremic toxins such as IS exist as protein-bound toxins in the blood.
Therefore, we tested IS action on hepcidin in HepG2 cells cultured with BSA
containing DMEM, and confirmed that IS augmented hepcidin mRNA expression
similarly in HepG2 cells cultured with DMEM with BSA as in those cultured with
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DMEM without BSA (Figure 1F). Moreover, there was no difference in basal hepcidin
expression regardless of BSA inclusion.
Involvement of oxidative stress in IS-induced hepcidin expression
IS causes oxidative stress and the consequent activation of the NF-ĸB
pathway in endothelial cells and proximal tubular cells [29-31]. Similar to previous
findings, IS caused oxidative stress in HepG2 cells in the present study (Figure 2A),
and the IS-induced oxidative stress was suppressed by tempol, a superoxide scavenger
(Figure 2B). IS-induced hepcidin upregulation was also suppressed by NAC or
BAY11-7082, an inhibitor of NF-ĸB (Figures 2C, D, and E). With regard to the
relationship between oxidative stress and the AhR pathway, tempol failed to block
IS-induced translocation of AhR to the nucleus from the cytosol (Figure 2F).
Conversely, AhR knockdown did not prevent IS-mediated oxidative stress in HepG2
cells (Figure 2G). Moreover, concomitant treatment with AhR siRNA and
BAY-11-7082 almost blocked IS-induced hepcidin expression (Figure 2H). These
results suggest that IS-induced hepcidin expression is also mediated via the oxidative
stress-NF-ĸB pathway, and that it is independent of the AhR pathway.
Changes in hepcidin levels in adenine-induced CKD mice
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To assess iron metabolism in CKD, we used mice with adenine-induced
CKD. In adenine-induced CKD mice, hepatic hepcidin expression and plasma hepcidin
concentration were significantly increased four weeks after the start of adenine
administration (Figure 3A and B). These increases in both hepatic hepcidin expression
and plasma hepcidin concentration were diminished by AST-120 treatment. As shown
in Figure 3C, hepcidin concentration was positively correlated with IS levels,
suggesting that IS is closely associated with hepcidin levels. These results indicate that
IS accumulation involves hepcidin regulation in CKD mice.
Alterations in tissue iron content in adenine-induced CKD mice
We examined the impact of IS accumulation on the tissue iron content in
adenine-induced CKD mice. As shown in Table 2, iron content was elevated in the
spleen and skeletal muscle in adenine-induced CKD mice, and these increases in iron
content were subsequently restored by AST-120 treatment. Duodenal iron content was
also increased in adenine-induced CKD mice, but it was not changed by AST-120
treatment. On the other hand, while CKD mice presented with decreased iron content
in the liver and kidney, AST-120 did not ameliorate this effect. The findings of
decreased plasma iron levels and increased plasma ferritin levels in the adenine-induced
CKD mice are compatible with functional iron deficiency, and both in the iron and
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ferritin levels in the blood were ameliorated by AST-120 treatment. These results
indicate impaired iron distribution and utilization in CKD mice.
Ferroportin expression in the duodenum and spleen
As described above, hepcidin regulates cellular iron efflux via the
internalization and degradation of FPN; hepcidin upregulation in CKD mice might
therefore reduce the expression of FPN. As expected, FPN expression was diminished
in the duodenum of CKD mice (Figure 4A), and its expression levels were restored by
AST-120 treatment. In contrast, splenic FPN expression was augmented in CKD mice,
and this change was also reversed by AST-120 (Figure 5A). In the spleens of CKD
mice, FPN mRNA expression was increased and IRP-IRE binding activity was reduced,
which was consistent with the increased FPN protein expression. The changes in FPN
mRNA and IRP activity were also improved by AST-120 treatment, which
corresponded with the reduction of FPN expression (Figure 5G and H). IRP-IRE
binding activity was regulated by iron content, and the change in IRP activity
corresponded with changes in splenic iron content. These findings suggest that FPN is
post-transcriptionally regulated, independently of hepcidin, in the spleens of CKD
mice.
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The protein expression of iron importers and iron storage in the duodenum and spleen
Next, we examined the protein expression of iron importers and iron storage
in the duodenum and spleen. In the duodenum, the expression levels of DMT1, FTH,
and FTL did not differ among the three groups (Figure 4B-D). Although no difference
in DMT1 expression was seen, levels of TfR were decreased, and those of FTH and
FTL were elevated in the spleens of CKD mice. These changes were all reversed by
AST-120 treatment (Figure 5B-E). Moreover, splenic hepcidin expression was
significantly reduced in adenine-induced CKD mice, which tended to be restored by
AST-120 treatment (Figure 5F).
Effect of IS removal on anemia in adenine-induced CKD mice
Adenine-induced CKD mice demonstrated microcytic hypochromic anemia
after four weeks of adenine treatment (Table 3). Treatment using AST-120 improved
impaired iron absorption and utilization in adenine-induced CKD mice, and renal anemia
was partly prevented by AST-120 treatment. CKD-induced elevation of plasma creatinine
was slightly suppressed by AST-120 at four weeks (Table 1), and renal EPO expression
remained at low levels in CKD mice, despite AST-120 treatment (Figure 6). In addition,
there were no differences in plasma creatinine and the degree of anemia between the
adenine-CKD mice and the adenine-CKD mice treated with AST-120 after two weeks of
adenine treatment and one week of AST-120 treatment (Tables 1 and 3). These data
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suggest that AST-120 restored iron incorporation and utilization by suppressing a
pathway that is hepcidin/FPN-dependent and EPO-independent.
Changes in mRNA expression of the inflammatory cytokines
IL-6 plays an important role in hepcidin regulation [32]. We examined the
participation of inflammatory cytokines in hepcidin expression in adenine-CKD mice. As
shown in Figure 7, the mRNA expression of IL-6, as well as IL-1ß and TNF-α, was
increased in the kidneys of adenine-CKD mice. In contrast, the mRNA expression of
those genes was decreased in the livers of adenine-CKD mice, indicating a lack of
involvement of inflammatory cytokines in hepcidin regulation in the livers of
adenine-CKD mice.
Direct effect of IS on hepcidin in mice with IS treatment
We examined whether IS has a direct effect on hepatic hepcidin expression
using mice that had been administered IS. IS treatment augmented hepatic hepcidin
mRNA expression as well as plasma hepcidin concentration (Figure 8A and B). IS
administration also induced mild anemia despite no difference in plasma creatinine
levels between the control mice and those that were administered IS (Figure 8C and
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Table 4). Therefore, IS directly affects hepcidin regulation independent of renal
function.
Discussion
In the in vitro experiments of the present study, IS augmented hepatic
hepcidin expression via a pathway that depended on both AhR and oxidative stress.
Similarly, hepatic and plasma hepcidin levels were increased in the in vivo experiments
using adenine-induced CKD mice. The CKD mice also showed decreased FPN
expression in the duodenum and increased splenic iron concentrations. The alterations
in iron metabolism in the CKD mice were ameliorated by AST-120, which removes IS.
These observations suggest, for the first time, the involvement of IS in iron metabolism
in CKD.
Hepcidin was first identified as an antimicrobial peptide and it plays an
important role in the regulation of iron metabolism [3]. Specifically, hepcidin regulates
cellular iron efflux via both the internalization and degradation of FPN [4]. Therefore,
CKD-related increases in hepcidin levels contribute to the intracellular sequestration of
iron, as well as impaired absorption of iron from the duodenum, and such changes
promote functional iron deficiency in CKD. Indeed, several studies have shown that
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the serum hepcidin concentration is elevated in CKD, which contributes to whole-body
iron dysregulation. Moreover, elevated serum hepcidin levels are correlated with serum
ferritin levels and inflammatory markers in patients with CKD [5]. Adenine-induced
CKD animals show increases in hepatic hepcidin, as well as abnormal iron metabolism
[6, 7]. In the present study, we found that hepatic hepcidin expression and plasma
hepcidin concentration were elevated in adenine-induced CKD mice. These hepcidin
increases were rectified by the removal of IS. The present study is the first to reveal the
association between IS and hepcidin regulation.
To investigate the mechanism by which IS regulates hepcidin concentrations,
we used HepG2 cells and found that IS also increased hepcidin expression in these
cells. Previously, Schroeder et al. demonstrated that IS is a ligand of AhR, and that IS
acts via AhR [28]. In the current investigation, IS promoted the translocation of AhR to
the nucleus from the cytosol in HepG2 cells, and the IS-induced hepcidin upregulation
was reversed by AhR silencing. Similarly, previous studies have shown that various IS
actions are prevented by AhR silencing [33]. Taken together, clearly the effect of IS on
hepcidin is exerted through an AhR-mediated pathway.
IS is known to cause oxidative stress; consequently, the toxin activates
NF-κB signaling [29-31, 34]. In the present study, IS-induced hepcidin augmentation
was suppressed by both a free radical scavenger and an NF-κB inhibitor, suggesting
that the IS-induced oxidative stress-NF-κB axis is involved in hepcidin regulation.
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However, IS-induced oxidative stress was not reduced by AhR siRNA, and tempol did
not inhibit the IS-induced translocation of AhR to the nucleus. In addition, IS-induced
hepcidin upregulation was almost completely abolished by the simultaneous inhibition
of the AhR and NF-κB pathways. These results suggest that IS/oxidative stress-induced
hepcidin expression occurs independently of any AhR-mediated pathway.
In contrast to our results, several studies have shown that hepcidin is
downregulated by oxidative stress induced by alcohol [35] or the hepatitis C virus [36].
However, pathophysiologically relevant H2O2 levels have been shown to upregulate
hepcidin expression via STAT3 [37]. In terms of the effect of NF-κB on hepcidin, a
previous study showed that LPS-induced hepcidin upregulation is mediated by NF-κB–
dependency, which is similar to our finding [38]. In contrast, ceramide-induced
hepcidin regulation is not involved in the NF-κB pathway [39]. Therefore, oxidative
stress and NF-κB have dual characteristics as either positive or negative regulators of
hepcidin.
Uremic solutes normally exist as protein-bound toxins, and several studies,
including the present study, used high concentrations of IS relative to the
concentrations in uremic CKD patients in the in vitro experiments [11, 40]. Therefore,
we tested the IS effect on hepcidin in HepG2 cells by using both the free concentration
(25µM) in albumin-free DMEM and the protein-bound maximum concentration (250
µM) in DMEM containing BSA. Twenty-five µM of IS induced an approximately
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twofold increase in hepcidin mRNA expression in HepG2 cultured with BSA-free
DMEM, and 250 µM IS also increased hepcidin mRNA expression in HepG2 cultured
with BSA-containing DMEM. In addition, there was no difference in basal hepcidin
mRNA expression in DMEM regardless of BSA inclusion, indicating no impact of
albumin on hepcidin expression (Figure 1F). Thus, hepcidin expression was
upregulated by IS at the free concentration and protein-bound concentration doses in
HepG2 cells under our experimental condition.
Inflammatory cytokines (i.e., IL-6) are also important factors in hepcidin
regulation [32]. As expected, the expression of IL-6, IL-1ß, and TNF-α mRNA was
upregulated in the kidney in CKD mice. However, it was decreased in the liver.
Although the reason for the discrepancy in inflammatory cytokine expression between
the kidney and liver remains unclear, inflammatory cytokines might not be associated
with the regulation of hepatic hepcidin in an adenine-induced CKD mouse model.
Regarding alterations in iron distribution in CKD mice, iron concentrations
in the spleen, duodenum, and skeletal muscle were increased. Plasma ferritin was also
increased, though plasma iron was decreased, indicating that iron absorption and
utilization were impaired. These alterations were mostly ameliorated by AST-120
treatment. It follows that IS removal, and the resulting inhibition of hepcidin, might
improve (1) iron metabolism and (2) iron utilization in CKD. Consistent with this
result, decreased expression of FPN in the duodenum was restored by AST-120
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treatment in CKD mice, indicating that IS removal affects hepcidin levels. Conversely,
CKD mice showed increased FPN expression in the spleen, which was reduced by
AST-120 treatment. It is not clear why the discrepancy of increased FPN expression in
the spleen combined with elevated hepcidin in the liver and serum is present in CKD
mice. FPN expression is controlled by both transcriptional and post-transcriptional
regulation, as well as by the translational regulation of hepcidin-dependent internalization.
In macrophages, FPN transcription is induced by iron, as well as by heme protein [41].
Additionally, FPN mRNA has an iron-responsive element in the 5′-region [42], and its
translation is therefore increased by high iron levels because it can bind to iron
regulatory protein 1 [43]. In the spleens of CKD mice, FPN mRNA was increased and
IRP activity was reduced, which is consistent with the understanding that increased
FPN protein expression is responsible for the transcriptional upregulation. Therefore,
we suggest that the increased FPN expression seen in CKD mice is likely responsible
for the accumulation of iron in the spleen, and that this accumulation overwhelms
hepcidin-mediated mechanisms. In addition, hepcidin expression has been observed in
not only the liver, but also the heart [44], kidney [45], brain [46], and spleen [47].
Although the function of extra-hepatic hepcidin remains unknown, it might influence
local iron regulation. In the present study, hepcidin expression was reduced in the
spleens of adenine-CKD mice, indicating the involvement of local hepcidin on the
regulation of splenic FPN expression. Further examination is necessary to clarify
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whether there is a coordinated regulation of (1) peripheral FPN expression or (2)
hepatic hepcidin levels.
CKD mice showed renal anemia compatible with iron-deficient anemia,
which is caused by iron sequestration and impaired iron utilization, as well as by
reduced renal EPO production. The renal anemia was slightly improved by AST-120
treatment, perhaps because consequent reductions in hepcidin restored iron utilization.
In previous studies, hepcidin inhibition ameliorated erythropoiesis in (1) a model of
CKD combined with renal anemia, (2) hepcidin-deficient mice, and (3) mice that had
been treated with a hepcidin inhibitor [7, 48]. This suggests that hepcidin inhibition
mobilizes iron and improves iron utilization. In the same way, the removal of IS using
AST-120 ameliorated iron accumulation in the spleen and skeletal muscle, as well as
elevated plasma ferritin levels. Conversely, the treatment reduced plasma iron levels in
CKD mice, indicating that iron mobilization in tissues with ectopic iron accumulation
had been improved. Moreover, AST-120 slowed the progression of renal dysfunction,
as estimated by plasma creatinine level; however, the decrease of renal EPO expression
in CKD mice was not changed by IS removal. Therefore, IS removal ameliorates renal
anemia via the restoration of iron utilization rather than through increased EPO
production. Additionally, cyanate, formed spontaneously from accumulated urea,
decreases EPO activity in order to induce EPO carbamylation [49, 50], which might
promote inadequate erythropoiesis in CKD.
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A recent clinical study (Evaluating Prevention of Progression in CKD
[EPPIC] trials) demonstrated that AST-120 fails to prevent disease progression in
patients with moderate to severe CKD [51]. Moreover, a subgroup analysis within the
EPPIC study revealed that AST-120 delays the primary end point (dialysis initiation,
kidney transplantation, or serum creatinine doubling) in American patients [52]. Thus,
it remains controversial whether IS removal prevents renal dysfunction in CKD.
Nonetheless, the uremic toxicity of IS accumulation causes dysfunction in various
organs through multiple pathways. Further examination is necessary to elucidate the
effect of AST-120 on renal anemia in CKD.
In conclusion, IS induces hepcidin production via a pathway that involves
both AhR and oxidative stress; this results in iron sequestration and impaired iron
utilization in CKD. AST-120 ameliorates iron metabolism by inhibiting hepcidin
increases, promoting iron mobilization, and ameliorating erythropoiesis. These findings
suggest that a therapeutic strategy of uremic toxin removal may be useful for correcting
impaired iron metabolism in CKD.
Acknowledgements
We appreciate the excellent technical advice given by the Support Center for Advanced
Medical Sciences, Institute of Biomedical Sciences, Tokushima University Graduate
School. We would like to thank Editage (www.editage.jp) for the English language
editing services.
25
Conflict of Interest Statement
The authors declare no competing financial interests.
Authors’ Contributions
1. Study conception and design: Y.I.
2. Experimentation and data acquisition: H.H., Y.I., and H.W.
3. Analysis and interpretation of data: H.H., Y.I., H.W., Y.H., Y.I.-I, M.I., Y.Z., K.T.,
L.M., K.I., K.T., and T.T.
4. Writing or critically revision of the manuscript for important intellectual content:
H.H., Y.I., Y.H., and T.T.
5. Final approval of the version to be published: All authors.
Funding
This work was supported by a research grant from the Kojinkai Foundation, the
President discretion research budget of the University of Tokushima, and JSPS
KAKENHI (Grant Number JP17H00503) to H.H. Further grants were provided to Y.I.
by the Ichiro Kanehara Foundation for the Promotion of Medical Sciences and Medical
Care, the pathophysiological research conference in chronic kidney disease
(JKFB15-12), and partly by the JSPS KAKENHI (Grant Number JP15K01716 to Y.I.,
Grant Number JP15H02898 to T.T.).
26
Reference
1. Collins AJ, Foley RN, Gilbertson DT, et al. The state of chronic kidney disease, ESRD, and morbidity and mortality in the first year of dialysis. Clin J Am Soc Nephrol 2009;4 Suppl 1:S5-11 2. Go AS, Chertow GM, Fan D, et al. Chronic kidney disease and the risks of death, cardiovascular events, and hospitalization. N Engl J Med 2004;351(13):1296-1305 3. Park CH, Valore EV, Waring AJ, et al. Hepcidin, a urinary antimicrobial peptide synthesized in the liver. J Biol Chem 2001;276(11):7806-7810 4. Nemeth E, Tuttle MS, Powelson J, et al. Hepcidin regulates cellular iron efflux by binding to ferroportin and inducing its internalization. Science 2004;306(5704):2090-2093 5. Zaritsky J, Young B, Wang HJ, et al. Hepcidin--a potential novel biomarker for iron status in chronic kidney disease. Clin J Am Soc Nephrol 2009;4(6):1051-1056 6. Hamada Y, Kono TN, Moriguchi Y, et al. Alteration of mRNA expression of molecules related to iron metabolism in adenine-induced renal failure rats: a possible mechanism of iron deficiency in chronic kidney disease patients on treatment. Nephrol Dial Transplant 2008;23(6):1886-1891 7. Sun CC, Vaja V, Chen S, et al. A hepcidin lowering agent mobilizes iron for incorporation into red blood cells in an adenine-induced kidney disease model of anemia in rats. Nephrol Dial Transplant 2013;28(7):1733-1743 8. Niwa T, Takeda N, Tatematsu A, et al. Accumulation of indoxyl sulfate, an inhibitor of drug-binding, in uremic serum as demonstrated by internal-surface reversed-phase liquid chromatography. Clin Chem 1988;34(11):2264-2267 9. Wu IW, Hsu KH, Lee CC, et al. p-Cresyl sulphate and indoxyl sulphate predict progression of chronic kidney disease. Nephrol Dial Transplant 2011;26(3):938-947 10. Barreto FC, Barreto DV, Liabeuf S, et al. Serum indoxyl sulfate is associated with vascular disease and mortality in chronic kidney disease patients. Clin J Am Soc Nephrol 2009;4(10):1551-1558 11. Vanholder R, Schepers E, Pletinck A, et al. The uremic toxicity of indoxyl sulfate and p-cresyl sulfate: a systematic review. J Am Soc Nephrol 2014;25(9):1897-1907 12. Nishikawa M, Ishimori N, Takada S, et al. AST-120 ameliorates lowered exercise capacity and mitochondrial biogenesis in the skeletal muscle from mice with chronic kidney disease via reducing oxidative stress. Nephrol Dial Transplant 2015;30(6):934-942 13. Yamamoto S, Zuo Y, Ma J, et al. Oral activated charcoal adsorbent (AST-120) ameliorates extent and instability of atherosclerosis accelerated by kidney disease in apolipoprotein E-deficient mice. Nephrol Dial Transplant 2011;26(8):2491-2497
27
14. Six I, Gross P, Remond MC, et al. Deleterious vascular effects of indoxyl sulfate and reversal by oral adsorbent AST-120. Atherosclerosis 2015;243(1):248-256 15. Inami Y, Hamada C, Seto T, et al. Effect of AST-120 on Endothelial Dysfunction in Adenine-Induced Uremic Rats. Int J Nephrol 2014;2014:164125 16. Yu M, Kim YJ, Kang DH. Indoxyl sulfate-induced endothelial dysfunction in patients with chronic kidney disease via an induction of oxidative stress. Clin J Am Soc Nephrol 2011;6(1):30-39 17. Iwasaki Y, Kazama JJ, Yamato H, et al. Accumulated uremic toxins attenuate bone mechanical properties in rats with chronic kidney disease. Bone 2013;57(2):477-483 18. Komiya T, Miura K, Tsukamoto J, et al. Possible involvement of nuclear factor-kappaB inhibition in the renal protective effect of oral adsorbent AST-120 in a rat model of chronic renal failure. Int J Mol Med 2004;13(1):133-138 19. Ito S, Higuchi Y, Yagi Y, et al. Reduction of indoxyl sulfate by AST-120 attenuates monocyte inflammation related to chronic kidney disease. J Leukoc Biol 2013;93(6):837-845 20. Chiang CK, Tanaka T, Inagi R, et al. Indoxyl sulfate, a representative uremic toxin, suppresses erythropoietin production in a HIF-dependent manner. Lab Invest 2011;91(11):1564-1571 21. Wu IW, Hsu KH, Sun CY, et al. Oral adsorbent AST-120 potentiates the effect of erythropoietin-stimulating agents on Stage 5 chronic kidney disease patients: a randomized crossover study. Nephrol Dial Transplant 2014;29(9):1719-1727 22. Tanaka T, Doi K, Maeda-Mamiya R, et al. Urinary L-type fatty acid-binding protein can reflect renal tubulointerstitial injury. Am J Pathol 2009;174(4):1203-1211 23. Al Za'abi M, Al Busaidi M, Yasin J, et al. Development of a new model for the induction of chronic kidney disease via intraperitoneal adenine administration, and the effect of treatment with gum acacia thereon. Am J Transl Res 2015;7(1):28-38 24. Tajima S, Ikeda Y, Enomoto H, et al. Angiotensin II alters the expression of duodenal iron transporters, hepatic hepcidin, and body iron distribution in mice. Eur J Nutr 2015;54(5):709-719 25. Ikeda Y, Imao M, Satoh A, et al. Iron-induced skeletal muscle atrophy involves an Akt-forkhead box O3-E3 ubiquitin ligase-dependent pathway. J Trace Elem Med Biol 2016;35:66-76 26. Ikeda Y, Tajima S, Izawa-Ishizawa Y, et al. Estrogen regulates hepcidin expression via GPR30-BMP6-dependent signaling in hepatocytes. PLoS One 2012;7(7):e40465 27. Tomosugi N, Kawabata H, Wakatabe R, et al. Detection of serum hepcidin in renal failure and inflammation by using ProteinChip System. Blood 2006;108(4):1381-1387 28. Schroeder JC, Dinatale BC, Murray IA, et al. The uremic toxin 3-indoxyl sulfate is a potent endogenous agonist for the human aryl hydrocarbon receptor. Biochemistry 2010;49(2):393-400
28
29. Masai N, Tatebe J, Yoshino G, et al. Indoxyl sulfate stimulates monocyte chemoattractant protein-1 expression in human umbilical vein endothelial cells by inducing oxidative stress through activation of the NADPH oxidase-nuclear factor-kappaB pathway. Circ J 2010;74(10):2216-2224 30. Shimizu H, Yisireyili M, Higashiyama Y, et al. Indoxyl sulfate upregulates renal expression of ICAM-1 via production of ROS and activation of NF-kappaB and p53 in proximal tubular cells. Life Sci 2013;92(2):143-148 31. Tumur Z, Shimizu H, Enomoto A, et al. Indoxyl sulfate upregulates expression of ICAM-1 and MCP-1 by oxidative stress-induced NF-kappaB activation. Am J Nephrol 2010;31(5):435-441 32. Nemeth E, Rivera S, Gabayan V, et al. IL-6 mediates hypoferremia of inflammation by inducing the synthesis of the iron regulatory hormone hepcidin. J Clin Invest 2004;113(9):1271-1276 33. Asai H, Hirata J, Hirano A, et al. Activation of aryl hydrocarbon receptor mediates suppression of hypoxia-inducible factor-dependent erythropoietin expression by indoxyl sulfate. Am J Physiol Cell Physiol 2016;310(2):C142-150 34. Shimizu H, Bolati D, Adijiang A, et al. NF-kappaB plays an important role in indoxyl sulfate-induced cellular senescence, fibrotic gene expression, and inhibition of proliferation in proximal tubular cells. Am J Physiol Cell Physiol 2011;301(5):C1201-1212 35. Harrison-Findik DD, Schafer D, Klein E, et al. Alcohol metabolism-mediated oxidative stress down-regulates hepcidin transcription and leads to increased duodenal iron transporter expression. J Biol Chem 2006;281(32):22974-22982 36. Miura K, Taura K, Kodama Y, et al. Hepatitis C virus-induced oxidative stress suppresses hepcidin expression through increased histone deacetylase activity. Hepatology 2008;48(5):1420-1429 37. Millonig G, Ganzleben I, Peccerella T, et al. Sustained submicromolar H2O2 levels induce hepcidin via signal transducer and activator of transcription 3 (STAT3). J Biol Chem 2012;287(44):37472-37482 38. Wu S, Zhang K, Lv C, et al. Nuclear factor-kappaB mediated lipopolysaccharide-induced mRNA expression of hepcidin in human peripheral blood leukocytes. Innate Immun 2012;18(2):318-324 39. Lu S, Natarajan SK, Mott JL, et al. Ceramide Induces Human Hepcidin Gene Transcription through JAK/STAT3 Pathway. PLoS One 2016;11(1):e0147474 40. Duranton F, Cohen G, De Smet R, et al. Normal and pathologic concentrations of uremic toxins. J Am Soc Nephrol 2012;23(7):1258-1270 41. Marro S, Chiabrando D, Messana E, et al. Heme controls ferroportin1 (FPN1) transcription involving Bach1, Nrf2 and a MARE/ARE sequence motif at position -7007 of the FPN1 promoter. Haematologica 2010;95(8):1261-1268 42. Abboud S, Haile DJ. A novel mammalian iron-regulated protein involved in intracellular iron metabolism. J Biol Chem 2000;275(26):19906-19912
29
43. Rouault TA. The role of iron regulatory proteins in mammalian iron homeostasis and disease. Nat Chem Biol 2006;2(8):406-414 44. Merle U, Fein E, Gehrke SG, et al. The iron regulatory peptide hepcidin is expressed in the heart and regulated by hypoxia and inflammation. Endocrinology 2007;148(6):2663-2668 45. Kulaksiz H, Theilig F, Bachmann S, et al. The iron-regulatory peptide hormone hepcidin: expression and cellular localization in the mammalian kidney. J Endocrinol 2005;184(2):361-370 46. McCarthy RC, Kosman DJ. Glial cell ceruloplasmin and hepcidin differentially regulate iron efflux from brain microvascular endothelial cells. PLoS One 2014;9(2):e89003 47. Peyssonnaux C, Zinkernagel AS, Datta V, et al. TLR4-dependent hepcidin expression by myeloid cells in response to bacterial pathogens. Blood 2006;107(9):3727-3732 48. Akchurin O, Sureshbabu A, Doty SB, et al. Lack of hepcidin ameliorates anemia and improves growth in an adenine-induced mouse model of chronic kidney disease. Am J Physiol Renal Physiol 2016;311(5):F877-F889 49. Mun KC, Golper TA. Impaired biological activity of erythropoietin by cyanate carbamylation. Blood Purif 2000;18(1):13-17 50. Park KD, Mun KC, Chang EJ, et al. Inhibition of erythropoietin activity by cyanate. Scand J Urol Nephrol 2004;38(1):69-72 51. Schulman G, Berl T, Beck GJ, et al. Randomized Placebo-Controlled EPPIC Trials of AST-120 in CKD. J Am Soc Nephrol 2015;26(7):1732-1746 52. Schulman G, Berl T, Beck GJ, et al. The effects of AST-120 on chronic kidney disease progression in the United States of America: a post hoc subgroup analysis of randomized controlled trials. BMC Nephrol 2016;17(1):141
Table 1. Characteristics of the control mice and adenine-CKD mice with or without AST-120 treatment
Data are presented as means ± SD; n = 4-15, respectively. *P < 0.05, **P < 0.01 vs. control mice at the same week. #P < 0.05, ##P < 0.01 vs. adenine diet at the same week.
IS; indoxyl sulfate.
1W 2W 4W
Control Adenine Control Adenine Adenine+AST120 Control Adenine Adenine +AST120
Body weight (g) 24.7 ± 2.2 22.5 ± 0.7 26.8 ± 1.1 20.8 ± 1.8** 20.4 ± 0.6** 28.2 ± 2.0 18.2 ± 1.5** 18.5 ± 1.3**
Right kidney weight (mg) 131.5 ± 12.5 163.8 ± 14.4* 143.0 ± 10.4 179.3 ± 17.6* 148.5 ± 14.1# 156.9 ± 10.5 152.1 ± 13.3 158.9 ± 12.2
Left kidney weight (mg) 122.3 ± 13.2 156.3 ± 14.2** 143.8 ± 13.4 170.3 ± 7.5 149 ± 15.2 149.7 ± 10.9 148.7 ± 17.5 153.9 ± 17.5
Plasma creatinine (mg/dL) 0.50 ± 0.07 0.87 ± 0.15** 0.31 ± 0.07 1.08 ± 0.21** 0.97 ± 0.03** 0.36 ± 0.11 1.67 ± 0.38** 1.33 ± 0.33**#
Table 2. Tissue iron content, plasma iron levels, and plasma ferritin concentration
Control Adenine Adenine + AST-120
Spleen (µg/g tissue weight) 6.1 ± 1.1 19.0 ± 7.5* 8.4 ± 0.9#
Liver (µg/g tissue weight) 19.9 ± 3.8 9.3 ± 1.3** 9.8 ± 1.3**
Duodenum (µg/g tissue weight) 8.0 ± 3.9 14.3 ± 6.9* 11.5 ± 5.7
Kidney (µg/g tissue weight) 7.6 ± 3.7 1.4 ± 0.7** 2.4 ± 1.5*
Gastrocnemius muscle (µg/g tissue weight) 3.6 ± 2.7 7.7 ± 5.4** 3.1 ± 0.6#
Plasma iron (µg/dL) 108.5 ± 16.8 78.6 ± 22.9* 111.7 ± 36.6#
Plasma ferritin (ng/mL) 504 ± 146 2842 ± 726** 1882 ± 571**##
Data are presented as means ± SD; n = 3-14, respectively. *P < 0.05, **P < 0.01 vs. control mice. #P < 0.05, ##P < 0.01 vs. adenine diet.
Table 3. Hematological data of the control mice and adenine-CKD mice with or without AST-120 treatment
Data are presented as means ± SD; n = 3-15, respectively. *P < 0.05, **P < 0.01 vs. control mice at the same week. #P < 0.05, ##P < 0.01 vs. adenine diet at the same week.
RBC; red blood cell, Hb; hemoglobin, Ht; hematocrit, MCV; mean corpuscular volume, MCH; mean corpuscular hemoglobin, MCHC; mean corpuscular hemoglobin
concentration, WBC; white blood cell, Plt; platelet.
1W 2W 4W
Control Adenine Control Adenine Adenine+AST120 Control Adenine Adenine+AST120
RBC (× 104/µL) 914 ± 79 726 ± 68* 857 ± 26 688 ± 93* 720 ± 40* 901 ± 63 643 ± 57** 718 ± 99**#
Hb (g/dL) 14.2 ± 1.2 11.4 ± 1.0* 13.7 ± 0.3 10.1 ± 1.4** 10.6 ± 0.7* 13.7 ± 0.9 8.8 ± 0.7** 10.1 ± 1.5**#
Ht (%) 43.4 ± 3.5 32.4 ± 3.1* 39.6 ± 0.9 29.7 ± 4.5** 31.4 ± 1.7** 40.7 ± 3.1 26.8 ± 2.5** 31.4 ± 7.0**#
MCV (fL) 47.7 ± 0.6 44.5 ± 0.5** 46.3 ± 0.5 43.0 ± 1.3** 43.7 ± 0.5** 45.3 ± 0.8 41.7 ± 1.0** 43.4 ± 3.3
MCH (pg) 15.5 ± 0.1 15.7 ± 0.6 15.9 ± 0.2 14.7 ± 0.2** 14.8 ± 0.2** 15.2 ± 0.4 14.0 ± 0.3** 14.0 ± 0.3**
MCHC (g/dL) 32.7 ± 0.4 35.2 ± 1.2** 34.5 ± 0.1 34.2 ± 1.0 33.9 ± 0.4 33.8 ± 1.3 33.5 ± 1.1 32.5 ± 2.3
WBC (/µL) 5200 ± 2100 3700 ± 700 3700 ± 1300 4300 ± 1800 4600 ± 2600 5200 ± 3200 2600 ± 1100** 2900 ± 1200*
Plt (× 104/µL) 51.8 ± 5.2 68.0 ± 12.6* 51.0 ± 12.2 66.3 ± 17.9 63.6 ± 17.6 45.2 ± 16.2 79.3 ± 15.3** 94.6 ± 18.7**
Table 4. Characteristics and hematological data of mice with vehicle- or IS-treatment for two weeks
Vehicle IS
Body weight (g) 27.6 ± 2.4 27.8 ± 0.3
Right kidney weight (mg) 155.3 ± 11.0 163.8 ± 22.5
Left kidney weight (mg) 152.0 ± 9.9 159.5 ± 8.9
Plasma creatinine (mg / dL) 0.37 ± 0.14 0.42 ± 0.22
RBC (× 104/µL) 955 ± 53 721 ± 62**
Hb (g/dL) 14.5 ± 0.9 11.3 ± 0.9**
Ht (%) 44.7 ± 2.9 33.4 ± 3.1**
MCV (fL) 46.5 ± 0.6 46.3 ± 0.5
MCH (pg) 15.2 ± 0.1 15.7 ± 0.4
MCHC (g/dL) 32.5 ± 0.5 33.9 ± 1.2
WBC (/µL) 4300 ± 900 5600 ± 1400
Plt (× 104/µL) 39.7 ± 7.0 50.7 ± 6.9
Data are presented as means ± SD; n = 4, respectively. *P < 0.05, **P < 0.01 vs. vehicle mice.
Figure legends
Figure 1. Effect of indoxyl sulfate (IS) on hepcidin expression in liver and HepG2 cells.
(A) IS induces hepcidin mRNA expression in HepG2 cells in a dose-dependent manner.
Values are expressed as means ± SD. *P < 0.05, **P < 0.01 (vs. vehicle treatment); n =
6-8 in each group. (B) Hepcidin concentration secreted from HepG2 cell to culture
media. Values are expressed as means ± SD. *P < 0.05 (vs. vehicle treatment); n = 4 in
each group. (C) IS translocates aryl hydrocarbon receptor (AhR) to the nucleus from the
cytoplasm in HepG2 cells. Left panel: representative protein expression levels of AhR
and tubulin, and semi-quantitative densitometry analysis of AhR expression in the
cytoplasm. Right panels: representative protein expression of AhR and Histone-H3, and
semi-quantitative densitometry analysis of AhR expression in the nucleus. Values are
expressed as means ± SD. *P < 0.05, **P < 0.01 (vs. time at 0 min); n = 5 in each group.
(D) Treatment with AhR siRNA inhibits IS-induced hepcidin upregulation in HepG2
cells. Forty-eight hours after siRNA transfection, cells were treated with either IS or
vehicle. Values are expressed as means ± SD. *P < 0.05, **P < 0.01; n = 14 in each
group. (E) Treatment with CH-223191 inhibits IS-induced hepcidin upregulation in
HepG2 cells. Cells were treated with either IS or vehicle 1 hour after CH-223191
pretreatment. Values are expressed as means ± SD. **P < 0.01; n = 3 in each group. (F)
High concentration of IS action on hepcidin mRNA in HepG2 cells cultured with or
without BSA-containing DMEM. Values are expressed as means ± SD. *P < 0.05, **P
< 0.01; n = 7 in each group.
Figure 2. Effect of IS-induced oxidative stress on hepcidin expression in HepG2 cells.
(A) Time course of IS-induced oxidative stress, as detected using 2 ′ ,7 ′
-dichlorofluorescin diacetate fluorescence. IS induces oxidative stress at 15 minutes or
later. Values are expressed as means ± SD. *P < 0.05, **P < 0.01 (vs. time at 0 min); n
= 7–8 in each group. (B) Pre-treatment with tempol inhibits IS-induced oxidative stress
in HepG2 cells. Cells were treated with either IS or vehicle for 24 hours after
pre-treatment with either vehicle or tempol. Values are expressed as means ± SD. *P <
0.05, **P < 0.01; n = 8 in each group. (C) The effect of tempol, a superoxide scavenger,
(D) N-acetyl cysteine, an-anti-oxidant agent, or (E) BAY-11-7082, an NF-κB inhibitor,
on IS-induced oxidative stress in HepG2 cells. Values are expressed as means ± SD. *P
< 0.05, **P < 0.01; n = 4-9 in each group. (F) Tempol has no inhibitory effect on
IS-induced AhR translocation to the nucleus from the cytosol. Values are expressed as
means ± SD. *P < 0.05, **P < 0.01; n = 8 in each group. (G) Effect of AhR silencing on
IS-induced oxidative stress. Values are expressed as means ± SD. **P < 0.01; n = 11–
16 in each group. (H) The concomitant effect of AhR siRNA transfection and NF-κB
inhibitor administration on IS-induced hepcidin expression in HepG2 cells. Values are
expressed as means ± SD. **P < 0.01; n = 4 in each group.
Figure 3. Changes in hepcidin levels in adenine-induced CKD mice with or without
AST-120 treatment. (A) Hepcidin mRNA expression. Values are expressed as means ±
SD. *P < 0.05, **P < 0.01, n = 4–11 in each group. (B) Plasma hepcidin concentration.
Values are expressed as means ± SD. **P < 0.01; n = 4–8 in each group. (C) Plasma
indoxyl sulfate concentration. Values are expressed as means ± SD. *P < 0.05, **P <
0.01; n = 4–8 in each group. (D) Positive correlation between plasma hepcidin and IS
concentration.
Figure 4. Changes in the expression of duodenal iron metabolism-related proteins in
mice. Upper panel: Representative immunoblots for (A) FPN, (B) DMT1, (C) FTH, (D)
FTL and protein staining. Lower panel: Semi-quantitative densitometric analyses of
DMT1, FPN, FTH, and FTL protein levels normalized to protein staining. Values are
expressed as means ± SD. **P < 0.01; n = 11–15 in each group.
Figure 5. Alterations in iron metabolism-related proteins in the spleen of mice. Upper
panel: Representative immunoblots for (A) FPN, (B) DMT1, (C) TfR, (D) FTH, (E)
FTL and tubulin. Lower panel: Semi-quantitative densitometric analyses of FPN,
DMT1, TfR, FTH, and FTL protein levels normalized to tubulin. Values are expressed
as means ± SD. **P < 0.01; n = 14–18 in each group. The mRNA expression of (F)
hepcidin and (G) FPN in the spleen of mice. Values are expressed as means ± SD. *P <
0.05, **P < 0.01; n = 7–12 in each group. (H) Upper panel: Representative IRP–IRE-
binding bands. Lower panel: Semi-quantitative densitometry analysis of IRP activity in
the spleen. *P < 0.05, **P < 0.01; n = 5 in each group.
Figure 6. Erythropoietin mRNA expression in the kidney. Values are expressed as
means ± SD. **P < 0.01; n = 10–11 in each group.
Figure 7. IL-6, IL-1ß, and TNF-α mRNA expression in the kidney and liver of control
mice and adenine-CKD mice. Values are expressed as means ± SD. *P < 0.05, **P <
0.01; n = 3-7 in each group.
Figure 8. (A) Hepcidin mRNA expression in the liver of vehicle-treated or IS-treated
mice at 2 weeks. Values are expressed as means ± SD. **P < 0.01 (vs. vehicle
treatment); n = 3–4 in each group. (B) Plasma hepcidin concentration. Values are
expressed as means ± SD. *P < 0.05 (vs. vehicle treatment); n = 7–11 in each group. (C)
Plasma indoxyl sulfate concentration. Values are expressed as means ± SD. **P < 0.05
(vs. vehicle treatment); n = 4–8 in each group.
(A) Figure 1 Hamano et al.
(B)
(E) (F)
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Figure 2 Hamano et al.
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Figure 2 continued
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BAY 11-7082 10µM
− + − +
(H)
0
200
400
600
800
1000
1200
-100 100 300 500
Figure 3 Hamano et al.
R2=0.73 P<0.01
(A)
Pla
sma
Hep
cidi
n-1
(ng/
ml)
Plasma Indoxyl sulfate (µM)
(D)
Control CKD
CKD+AST
0
1
2
3
4
5
6
Hep
atic
hep
cidi
n m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
** *
AST(−) Control
Adenine-CKD
AST(+)
(B)
0
200
400
600
800
1000
1200
1400P
lasm
a H
epci
din-
1 (n
g/m
l)
(C)
0
100
200
300
400
Pla
sma
indo
xyl s
ulfa
te (µ
M)
AST(−) Control
Adenine-CKD
AST(+) AST(−) Control
Adenine-CKD
AST(+)
** ** ** *
00.5
11.5
22.5
0
0.5
1
1.5
2
FTH
pro
tein
(R
elat
ive
fold
cha
nge)
FTL
prot
ein
(Rel
ativ
e fo
ld c
hang
e)
(C) (D)
0
0.5
1
1.5
2
0
0.5
1
1.5
2
AST(−) Control Adenine-CKD
AST(+)
FPN
pro
tein
(R
elat
ive
fold
cha
nge)
DM
T1 p
rote
in
(Rel
ativ
e fo
ld c
hang
e)
(A) (B)
* *
Ponceau-S
FTL
Ponceau-S
FTH
Ponceau-S
DMT1
Ponceau-S
FPN
Figure 4 Hamano et al.
AST(−) Control Adenine-CKD
AST(+)
AST(−) Control Adenine-CKD
AST(+) AST(−) Control Adenine-CKD
AST(+)
(B) (C)
0
0.5
1
1.5
2
0
0.5
1
1.5
2
DM
T1 p
rote
in
(Rel
ativ
e fo
ld c
hang
e)
TfR
pro
tein
(R
elat
ive
fold
cha
nge)
AST(−) Control Adenine-CKD
AST(+) AST(−) Control Adenine-CKD
AST(+)
Figure 5 Hamano et al.
** Tubulin
TfR
Tubulin
DMT1
Tubulin
FPN
0
0.5
1
1.5
2
2.5
FTH
pro
tein
(R
elat
ive
fold
cha
nge)
(D)
* * **
Tubulin
FTH
AST(−) Control Adenine-CKD
AST(+) 0
0.5
1
1.5
2
2.5FT
L pr
otei
n (R
elat
ive
fold
cha
nge)
(E) Tubulin
FTL
AST(−) Control Adenine-CKD
AST(+)
** * **
(A)
0
0.5
1
1.5
2
2.5
FPN
pro
tein
(R
elat
ive
fold
cha
nge)
AST(−) Control Adenine-CKD
AST(+)
* **
Figure 5 continued
(F) H
epci
din
mR
NA
(Rel
ativ
e fo
ld c
hang
e)
*
AST(−) Control
Adenine-CKD
AST(+) 0
0.5
1
1.5
2
2.5
3
(G)
FPN
mR
NA
(R
elat
ive
fold
cha
nge)
AST(−) Control
Adenine-CKD
AST(+) 0
2
4
6
8
10** *
IRP
activ
ity
(Rel
ativ
e fo
ld c
hang
e)
AST(−) Control
Adenine-CKD
AST(+)
(H)
IRP
0
0.5
1
1.5 ** *
Figure 6 Hamano et al.
0
0.5
1
1.5
2
EP
O m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
AST(−) Control Adenine-CKD
AST(+)
** **
Figure 7 Hamano et al.
010203040
00.5
11.5
2
0
10
20
30
00.5
11.5
2
0
5
10
15
00.5
11.5
2
IL-6
mR
NA
(R
elat
ive
fold
cha
nge)
IL-6
mR
NA
(R
elat
ive
fold
cha
nge)
TNF-
α m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
TNF-
α m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
IL-1
β m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
IL-1
β m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
Control Adenine- CKD Control Adenine-
CKD
Control Adenine- CKD Control Adenine-
CKD
Control Adenine- CKD Control Adenine-
CKD
*
**
* *
*
**
Kidney Liver
Figure 8 Hamano et al.
0
0.5
1
1.5
2
2.5
Hep
cidi
n m
RN
A
(Rel
ativ
e fo
ld c
hang
e)
**
Vehicle IS 0
5
10
15
20
25
30
*
Vehicle IS
Pla
sma
indo
xyl s
ulfa
te (µ
M)
(B) (C) (A)
0
20
40
60
80
100
120
140
Vehicle IS
Pla
sma
hepc
idin
-1 (n
g/m
l)
*